Vane for gas cylinder



Oct. 8, 1968 fi- 3,404,871

VANE FOR GAS CYLINDER Original Filed Feb. 17, 1964 2 Sheets-Sheet 1 INVENTOR By ALFRED H. TAVLO/flJ/P.

A T TORNE l Oct. 8, 1968 H TAYLOR VANE FOR GAS CYLINDER 2 Sheets-Sheet 2 Original Filed Feb. 17, 1964 Ilium.

"HIM:

M/l ENTOR By ALFRED H. TAVLOR,JR.

ATTORNEY United States Patent 3,404,871 VANE FOR GAS CYLINDER Alfred H. Taylor, Millington, N.J., assignor to Air Reduction Company, Incorporated, New York, N.Y., a corporation of New York Original application Feb. 17, 1964, Ser. No. 345,240, now Patent No. 3,241,819, dated Mar. 22, 1966. Divided and this application Sept. 16, 1965, Ser. No. 508,882

14 Claims. (Cl. 259-114) ABSTRACT OF THE DISCLOSURE The invention relates to the use of vanes inside of containers to intermix the contents of the containers. The vanes are constructed and mounted so that they can move under the influence of gravity relative to the container walls.

This application is a division of application Ser. No. 345,240, filed on Feb. 17, 1964, now US. Patent No. 3,241,819.

This invention relates to means for promoting the mixture of gases contained within a gas container.

More specifically, this invention relates to an internal vane or paddle structure for a gas container, normally a gas cylinder, used to promote, effect, or maintain the intermixture of the several gaseous components introduced into said gas container, with or without premixing.

The preparation and maintenance of accurately proportioned, homogeneous mixtures of two or more gases in a gas cylinder is a recurrent problem. For example, in one type of gas cylinder, gases under compression are supposed to be intermixed and maintained at a ratio of 75% argon and 25% carbon dioxide. There is atendency for the gases to remain separated, since the gases are normally not introduced at the same time, but rather the heavier carbon dioxide is introduced into the cylinder first. When mixture does occur, it occurs very slowly, thus impeding the usefulness of the filled cylinder, since early withdrawal of gas will result in the gas not being in the proper mixture, which is in itself undesirable, resulting in an imbalance in the ratio of the gas constituents still in the cylinder.

There have been numerous proposals for promoting the more rapid mixture of gases of gas storage cylinders, of which the argon-carbon dioxide cylinder is one example. None of the previous proposals for effecting complete and rapid mixture of gases introduced into a cylinder have been completely successful. For example, it has been a common practice to roll the cylinder back and forth on a surface, after completing the filling operation of said cylinders with the gases contained therein, in order to effect said mixture of gases. However, said rolling operation is inefficient since it requires wide floor space, operator attention and much time. It is to be noted that when filled gas cylinders containing more than one gas therein are moved solely in a random matter, for example, as in transport, there is often insufficient motion to effect rapid or significant mixture of the gases.

Other methods for effecting mixture of various gases within a cylinder include: vibrating the cylinder, alternate heating and cooling of the cylinder walls, adding rods which roll inside the cylinder when the cylinder itself is rolled, moving hermetically sealed mechanically or magnetically actuated shafts in a cylinder, or simply allowing the cylinder to stand for long periods of time. I

The above methods are either ineffective or extremely unsatisfactory, since, for example, they are slow to cause mixture of gases, and require deliberate manual action to accomplish whatever mixture is accomplished.

It is an object of this invention to provide means for 3,404,871 Patented Oct. 8, 1 968 aiding quick and effective mixture of the cylinder. 7

It is a further object of this invention to provide structure internally mounted in a gas cylinder for intermixing the various gases contained therein.

It is further an object of this invention to provide for hastening intermixture of gases contained within a cylinder as a result of utilizing structure mounted internally of the cylinder.

These and other objects will become more apparent in connection with the more detailed description and drawings relating thereto which follow:

The structure of one embodiment of this invention for affecting more rapid intermixture of gases is a vane or paddle placed within a gas cylinder in such a manner that it can move independently, continuously and randomly under the influence of gravity, whenever the cylinder is moved. Movement of the vane within the cylinder with respect to the confining cylinder walls continuously wafts or displaces the gaseous contents, thus promoting the formation of gas currents which promote mixing of the gases within the cylinder within a short period of time. The gas mixing vane may be mounted in any desired fashion within the cylinder; for example, mounted from the inner valve so as to swing freely and be moved by the action of gravity as a result of the flexibility of the mount, of the mounting material, or of the vane itself. The vane may be mounted in any desired manner, for example, so as to pivot, hinge or swing freely, or it may simply stand within the cylinder. Any variety of mechanical means may be used to mount the vane within the cylinder.

In a second embodiment of the invention, the vane structure comprises a series of slats not unlike a venetian blind, hung from a shaft in such a way as to displace the gases in the cylinder when the cylinder is moved, thus effecting intermixture.

In a third embodiment of the invention the vane structure is comprised of paddle elements, some of which are fixed to a shaft within the cylinder, and some of which are movable on said shaft. The fixed paddle elements rotate with the shaft and cylinder, thereby producing a movement of gas which is opposed by the movable paddles. The opposing action of the several paddles produces effective gas mixing.

The invention will now be described in further detail in connection with the following drawings:

FIGURE 1 shows a gas container with mixing vane or paddle structure mounted therein.

FIGURE 2 shows one method of mounting the vane structure of FIGURE 1.

FIGURE 3 shows a second method of mounting the vane structure of FIGURE 1.

FIGURE 4 shows a second form of vane structure mounted in a container.

FIGURE 5 shows another form of vane structure mounted in a container.

Within the interior of a gas container 1 in the shape of a cylinder is mounted vane structure in the form of a ribbon-like vane or paddle 2. Said vane 2 may be of any desired length, shape, and of any variation of width and thickness desired. For maximum results, due to maximum gas displaced, the vane should be almost as long as the interior length of the cylinder and mounted on the longitudinal axis of the cylinder. It is preferred that the vane 2 be relatively thin and flexible so that wafting action may occur. One vane of the type shown in FIGURE 1 constructed and satisfactorily used according to this invention was 6 inches wide x 48 incheslongx 0.002 inch thick. The vane structure may be made of any one of a number of different materials, such as stainless steel, copper, tin, brass, plastic, or other synthetic material, etc.

gases of a gas The vane 2 may be mounted in the cylinder 1 in any desired manner, such as by attaching it to the valve 3 of the cylinder 1 as shown at 4 in FIGURE 1. Said method of attachment to the valve of the cylinder may be as the result of brazing, as shown generally at 5 in FIGURE 2 or as the result of a pin and strip connection as shown generally at 6 in FIGURE 3 (pin 7 attaching strip 8 to the valve 3, said trip 8 attached by pins or rivets 9 to the vane 2). The vane 2 may be flexible so as to waft and displace the surrounding gases, as vane 2 within the cylinder is held under the action of gravity upon moveof the cylinder. The strip 8 may be flexible to allow for Wafting of the vane 2, even if the vane 2 is rigid. Obviously, the vane structure may be attached to the valve 3 in any desired manner, FIGURES 2 and 3 merely illustrating two possible modes of attachment. As pointed out earlier, the vane structure, such as vane 2, may be flexible so as to promote mixture of the gases due to wafting, even if a rigid mounting of said vane to the cylinder is employed; or the mounting of the vane structure within the cylinder may be such as to allow the vane structure to move, even if the vane structure is rigid, such as by use of a flexible strip 8, so as to promote mixing.

One manner of inserting the vane 2 shown in FIGURE 1 into the cylinder 1 is by coiling it into a tight roll and passing it easily through the valve opening Said vane then springs open to the flat fan-like structure shown in FIG- URE 1. Other modes of introducing the vane into the cylinder may also be employed, and said method of introducing said vane into the cylinder is not the subject of this invention.

After the mixing vane shown in FIGURE 1 has been introduced into the cylinder, the vane fans or wafts about in random fashion, under the influence of gravity, upon the introduction of gas into the said cylinder or upon any movement of said cylinder, etiher because it is flexible or because of its flexible mount within the cylinder, thus causing intermixture of the gases. Even where the prior methods of intermixing the gases are still used, the mixing vane promotes more rapid intermixture of said gases, thus producing a more useable gas charged cylinder. The vane also insures that the mixed gases are remixed if they should become separated as for example when freezing weather causes liquefaction of one component (i.e. CO in the CO -argon example).

The following figures compare two samples of the gas obtained from a cylinder employing a 4 inches wide x 48 inches long x 0.002 inch thick mixing vane (mixer cyl.) according to FIGURE 1 to two samples of gas obtained from a cylinder without the vane (std. cyl.), seven days after the cylinders were 75% filled with argon gas and 25% filled with carbon dioxide gas. It is apparent from the figures that the heavier carbon dioxide gas more completely mixed with the argon gas where the mixing vane was employed.

Percent 002 (V./V.)

Furthermore, a gas cylinder employing a vane of the construction shown in FIGURE 1 was compared to a cylinder not employing the vane structure at short intervals after filling said cylinders to determine the rapidity of the inter-mixture of gases. In this case both cylinders were 25% filled with carbon dioxide gas and 75% filled with argon gas and then said cylinders were tested at the time intervals indicated to determine the composition of the product gas. It will be noted that intermixture of the gases in a cylinder with the mixing vane (mixer cyl.) was effected at a faster rate than in the standard cylinder (std.

cyl.) without the mixer vane. A 6 inch wide x 48 inch long x 0.002 inch thick vane was employed.

Percent 002 -I J The above data indicates that the presence of the mixer vane improved the mixing of the standard cylinder contents, and speeded said mixing. It is apparent from the above figures that the mixer vane results in more rapid intermixture of the gases of a gas cylinder. The vane also aids the continued inter-mixture of the gases within the cylinder, reducing separation due, for example, to liquefying one component.

In the embodiment of this invention shown in FIGURE 4, the vane structure is comprised of a series of slats 11, the vane structure being not unlike a venetian blind in appearance, the slats being either flexible or rigid, as desired. The slats 11 are movably mounted to each other and finally to a centrally mounted shaft 12, by use of connecting structure 13, such as loops. The shaft 12 is fixedly mounted at its ends within cylinder 1. The connecting structure 13 allows for movement of the slats 11 under the influence of gravity in relation to the shaft 12 and the cylinder 1. When the container 1, shown as a cylinder, of FIGURE 4 is rotated or moved, the slats 11 move under the influence of gravity on shaft 12 in relation to the walls of container 1 and cause intermixture of gases contained within the container. This intermixture is increased as a result of the great area covered by the vane structure, and its flexible construction.

-In the embodiment of the invention shown in FIGURE 5, the vane structure is comprised of vane or paddle elements 14 fixedly mounted in centrally mounted shaft 15, which in turn is fixedly mounted on container 1, shown as a cylinder, and vane or paddle elements 16 movably mounted on shaft 15, as, for example, by the use of loops 13, such as described in relation to FIGURE 4. The movable vane or paddle elements 16 may be in the form of slats, as shown in FIGURE 4, and move under the action of gravity. The fixed vanes 14 rotate with the shaft and container, thereby producing a movement of gas which is opposed by the movement of gases directed by the movable vanes 16, the opposing action of the several vanes producing most effective gas intermixture.

The mounting of the shaft to the cylinder in FIGURES 4 and 5 is described above as a fixed mounting. However, it is within the spirit of this invention to make such mounting of such a type that rotational movement of said shaft in relation to the cylinder is possible. Limited rotational movement of vane or paddle elements mounted on a fixed shaft within a container so as to fan or stir the gas is also within the purview of my invention. The vane or paddle elements of FIGURES 4 and 5 may be formed of rigid or flexible material.

It is pointed out that many gas containers in existance at this time can be modified so as to facilitate the addition of mixing vane structure. Of course, containers made in the future can be constructed so as to include said mixing vane structure or said vane structure can be added at a future date.

As discussed previously, the vane or paddle structure of the embodiments of this invention may also be mounted in containers containing vapors, which, under certain conditions, may liquify, effecting a separation of the mixture. Although the vane structure is shown as mounted on the longitudinal axis of the container in the figures as is preferred because of maximum effect, the mounting does not necessarily have to be along said axis but rather may be displaced.

The term cylinder" is descriptive of the storage container generally known in the trade and is not limited to a cylindrical shape.

The subject matter of this invention is not limited to any apparatus or method of using said apparatus other than what is within the spirit of that set forth in the following claims.

I claim:

1. A container for a plurality of gasses, mixing means, said mixing means mounted within said container for movement under the action of gravity in relation to the container, said mixing means extending along the greater part of the length of said container, said mixing means promoting rapid and continued intermixture of the gas contents of said container, said mixing means comprised of a plurality of slats, a shaft mounted within said container, each slat movably connected to another slat, one of said slats movably connected to said shaft, so that motion of said container will cause movement of the slats due to the action of gravity and result in displacement of the gases within the container.

2. A container as set forth in claim 1, the shaft being fixedly mounted to the container.

3. A container as set forth in claim 1, loop means effecting each of the movable connections previously recited.

4. A container, mixing means mounted within said container, said mixing means extending along the greater part of the length of said container, said mixing means promoting intermixture of the contents of said container, said mixing means comprising a plurality of vane elements, a shaft mounted Within said container, means mounting said elements on said shaft so that said elements are spaced from one another and at least one vane element movably mounted on said shaft for relative movement thereto.

5. A container as set forth in claim 4, at least one of the vane elements being fixedly mounted to said shaft.

6. A container as set forth in claim 5, the shaft being fixedly mounted to the container.

7. A container as set forth in claim 5, loop means effecting each movable mounting.

8. A container, mixing means within said container comprising, a supporting member mounted in said cylinder, means mounting a first slat on said member for relative movement therebetween, means mounting a second slat on said first slat for relative movement between said slats, said mounting means allowin said slats to move under the influence of gravity.

9. Vane structure for use within a container containing a plurality of gases, said vane structure comprising at least two vane elements mounted within the container, means mounting at least one of said elements for movement relative to the Walls of the container under the influence of gravity, means fixedly mounting at least one of the elements in said container so that relative movement takes place between said elements when said first element is moved under the influence of gravity, said relative movement between said elements causing intermixing of said gases.

10. Vane structure as claimed in claim 9 in which said mounting means comprises an elongated shaft, said vfitne elements being longitudinally spaced along said s aft.

11. Vane structure as claimed in claim 10 including means for movably mounting said shaft relative to said container.

12. Vane structure as claimed in claim 10 including means for fixedly mounting said shaft relative to said container.

13. A storage cylinder, an elongated shaft mounted in said cylinder, at vane, means mounting said vane to said shaft for relative movement with respect to said shaft, said mounting means comprising a plurality of spaced movable connections so that said vane is free to move under the influence of gravity.

14. A cylinder as set forth in claim 13 in which said vane is substantially planar.

References Cited UNITED STATES PATENTS 208,707 10/ 1878 Blackwill 259-88 X 222,225 12/1879 Anderson 259-88 X 466,671 1/1892 Gale 25988 ROBERT W. JENKINS, Primary Examiner. 

